Abstract:
Concentrating solar power technologies can be applied to reduce the cost and carbon footprint of zinc melting
processes. This study aims to improve the knowledge related to small-scale solar melting using a dish concentrator. This technology can be applied to zinc production as well as a range of small-scale applications, such as
casting, recycling, galvanisation, and thermal storage. An experimental and analytical analysis of a rotating
cylindrical cavity receiver for the indirect melting of zinc metal using concentrated solar power is presented. A
multi-facet parabolic dish with an incident area of 2.85 m2 was considered together with a rotating cylindrical
cavity receiver. The receiver had an aperture diameter of 0.2 m and the capacity for housing 17 kg of zinc. Five
experimental test runs were executed, during which up to 73.5 % of the zinc inventory could be tapped from the
receiver in its molten state, and average thermal efficiencies of up to 42 % were achieved. A predictive analytical
model considering wind speed, wind direction, and direct normal irradiance was developed and validated against
experimental data. A heat transfer efficiency factor was experimentally determined to account for voids in the
zinc feedstock. The model was used to predict that approximately 41 kg of molten zinc could be tapped from the
experimental setup throughout a typical day with a peak direct normal irradiance of about 900 W/m2 and an
average wind speed below 2 m/s. A case study highlighted that energy savings of 0.6 kWh are achievable per
kilogram of zinc processed by concentrated solar power rather than the conventional induction furnace.
